A railing assembly includes a bottom rail and a top rail extending parallel thereto and spaced apart therefrom. Both rails include a beam defining through-holes and corresponding pocket-holes located opposite from the other rail to define ledges facing away from the other rail. A plurality of balusters of light-transmissive material each extend between the bottom rail and the top rail, through a corresponding through-hole and pocket-hole in each railing. Retaining rings are disposed around each of the balusters within each of the pocket-holes for engaging the ledges and thereby holding the balusters to each rail. Each rail may include a plate of light-transmissive material extending in a plane adjacent the beam and configured to project light along a length thereof. One or more illumination sources are disposed in the top rail and/or the bottom rail to direct light into the balusters and/or the plate(s) to provide options for multiple illumination effects.

A standoff for mounting panels such as glass panels in architectural applications include a plurality of parts that are first mounted to the panel and are then used to identify the locations for the anchor fasteners in the support structure or to locate the anchor fasteners as they are driven into the support structure. One configuration includes a bushing that defines a through opening. The bushing is placed through an opening the panel to be mounted. A barrel defining its own opening is then placed on the portion of the bushing that extends from the panel. The through hole of the bushing is aligned with the opening of the bushing such that an anchor fastener can pass through the bushing and the barrel into a support structure to which the panel is to be mounted.

A balustrade arrangement according to this disclosure comprises a plurality of slats of monolithic toughened glass arranged in series substantially along a lateral direction. The slats each have a width in the lateral direction up to 300 mm from a first lateral side to a second lateral side of a slat. Adjacent slats are spaced apart from each other by a spacing gap of at least 6 mm, the spacing gap being smaller than the width of the slats. The slats are arranged so that, when one slat is removed from the balustrade to form a breakage gap between adjacent remaining slats, the width of the breakage gap in the lateral direction is at most 500 mm. Also disclosed is a balcony incorporating such a balustrade and a method for the installation of such a balustrade.

The invention relates to an arrangement for securing a vertical panel (14) in a longitudinal groove (28), the panel (14) comprising an inner face (20) and an outer face (22), the securing being carried out by transverse clamping between transversely opposed wedges (36A, 36B; 38A, 38B), the arrangement comprising: an upper outer wedge (38A) and a lower outer wedge (38B) which are each positioned between an outer face (34) of the groove (28) and the outer vertical face (22) of the panel (14); at least two movable transmission members (62A, 62B) which are each capable of transmitting a sliding force to an associated outer wedge (38A, 38B), the force being applied from an inner side (24) of the panel (14); the arrangement is characterized in that the upper and lower outer wedges (38A, 38B) slide vertically upwards from the released position thereof to the clamped position thereof above the released position.

A wall supporting device, for supporting a wall segment, has a base portion, above which the wall segment is locatable. The base portion is for receiving a lighting device, and has a top surface on which a portion of the lighting device is restable. The device also has an arm portion, extending from the base portion, to which the wall segment is securable. A gap is defined between the portion of the lighting device resting on the top surface and a side surface of the device.

A device for securing a panel in a groove is provided. The securing device includes a cradle housed in the groove comprising a sole bearing on the bottom of the groove and a vertical outer flange interposed transversely between an outer face of the panel and a face of the groove; a first upper wedge which is interposed between a fixed upper ramp of the groove and an inner face of the panel; and a second lower wedge which is interposed transversely between a fixed lower ramp of the groove and the inner face of the panel. The lower ramp is carried by an inner vertical flange of the cradle.

A plate stabilizing device is configured to couple with an external U-shaped plate profile. The device includes an external segment, corresponding in shape to the external U-shaped plate profile and configured to fit therein. The external segment includes a socket adapted to at least partially accommodate an external alignment tool through a passage serving as a turning point for the external alignment tool, and an internal segment that is configured to accommodate a bottom portion of the plate. The internal segment comprising an alignment tool wedge-like portion capable of accommodating a tip of the alignment tool.

A railing assembly includes a bottom rail and a top rail extending parallel thereto and spaced apart therefrom. Both rails include a beam defining through-holes and corresponding pocket-holes located opposite from the other rail to define ledges facing away from the other rail. A plurality of balusters of light-transmissive material each extend between the bottom rail and the top rail, through a corresponding through-hole and pocket-hole in each railing. Retaining rings are disposed around each of the balusters within each of the pocket-holes for engaging the ledges and thereby holding the balusters to each rail. Each rail may include a plate of light-transmissive material extending in a plane adjacent the beam and configured to project light along a length thereof. One or more illumination sources are disposed in the top rail and/or the bottom rail to direct light into the balusters and/or the plate(s) to provide options for multiple illumination effects.

A selectively inserted panel securement secures a panel into a balustrade, and a fastener affixes the panel securement into a top rail of the balustrade. The panel securement comprises a base inserted into a recess within the bottom of the top rail, a riser affixed on one end to the base and having a contact surface adjacent to a panel side edge that restricts panel movement in a first axial direction; and a panel retaining member extending perpendicularly from the riser on a second end distal to the base. The panel retaining member is inserted into a top railing channel and restricts panel movement in a second axial direction. A notch in the base secures the panel in a third axial direction, thereby preventing movement of the panel in three orthogonal axes. The fastener fastens the selectively inserted panel securement to the top rail within the channel.

A system for leveling and securing a partition, including a base or shoe for receiving the partition, and a channel or slot formed in the base by at least a first sidewall, an opposing second sidewall, and a lower wall positioned at least in part between the first and second sidewalls. The system further includes a rocker assembly and a clamp assembly positioned within the slot. The rocker assembly includes a stationary component positioned adjacent the first sidewall and a pivoting component pivotably connected to the stationary component on a side of the stationary component opposite the first sidewall. The clamp assembly may include a stationary block adjacent the second sidewall, a first sliding block slidably connected to the stationary block and adjustable by a first fastener, and a second sliding block slidably connected to the stationary block and adjustable by a second fastener.